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Author: Qian Zhong
Publisher:
ISBN:
Category : Metal oxide semiconductors, Complementary
Languages : en
Pages :
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Book Description
Electromagnetic waves in the millimeter (mm) and sub-millimeter wave (sub-mm) frequency ranges have caught a lot of attention. The waves at these frequencies can interact with gas molecules possessing dipole moments and change their rotational states. This phenomenon can be utilized for fast scan rotational spectroscopy to detect gas molecules and measure their concentrations. Rotational spectrometers have a wide range of applications including indoor air quality monitoring, detection of harmful gas leaks, breath analyses for monitoring bodily conditions and many others. At the mm and sub-mm wave frequencies, a large bandwidth is available for extremely high data rate communication. Communication over a dielectric waveguide at these frequencies with a loss less than 10dB/m has been proposed to mitigate the complexity of communication over copper wires as well as the integration challenges for optical communication that are being developed to meet the ever-increasing bandwidth demand. The advances of complementary metal-oxide-semiconductor (CMOS) technology have enabled the implementation of mm-wave and sub-mm wave frequency circuits with reduced cost and increased system integration and complexity. A receiver with a radio frequency front-end bandwidth of 95 GHz and noise figure of 13.9 -19 dB for a rotational spectrometer is demonstrated in 65-nm CMOS. In addition, a 300-GHz QPSK transmitter with a 30-Gbps data rate is demonstrated that consumes 180mW for dielectric waveguide communication. The system level tradeoff of a receiver for rotational spectroscopy is first analyzed with a focus on the noise mechanism. A detailed signal-noise interaction derivation due to a 2nd order non-linearity is presented and signal to noise ratio degradation is shown for different modulation scenarios. A receiver front-end using a broadband antenna backed by a phase compensated artificial magnetic conductor reflector, a floating body antiparallel diode pair as the mixing device and a multi-mode isolated broadband hybrid is demonstrated. The receiver also includes an on-chip LO generator using frequency multipliers and capacitive neutralized power amplifiers, an IF cascode low noise amplifier and a baseband power detector. The receiver exhibits a responsivity of 400-1200 kV/W and noise equivalent power of 0.4 to 1.2 pW/√Hz at 225 to 280 GHz. Detection of Ethanol, Propionitrile (EtCN), Acetonitrile (CH3CN) and Acetone in a mixture is demonstrated using the receiver in a rotational spectroscopy setup. This is the first demonstration that a CMOS receiver can be used for rotational spectroscopy and that a CMOS integrated circuit can support an existing application at frequencies above 200 GHz. A heterodyne transmitter with a current mode logic modulator, a multi-stage constant gain and group delay wideband data buffer using coupled resonators, a double balance passive up-conversion mixer using a Marchand balun which acts as built-in LO spur traps, and a quadrature oscillator with quadrature calibration are demonstrated. The transmitter generates the required RF power for the system of -6 dBm and supports a maximum data rate of 30Gbps while consuming 180mW of power resulting in an energy efficiency of 6 pJ/bit. The single channel data rate is almost 2X higher than that of the previously reported CMOS QPSK transmitter and the energy efficiency is among the highest of CMOS QPSK transmitters operating at the similar frequency range.
Author: Qian Zhong
Publisher:
ISBN:
Category : Metal oxide semiconductors, Complementary
Languages : en
Pages :
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Book Description
Electromagnetic waves in the millimeter (mm) and sub-millimeter wave (sub-mm) frequency ranges have caught a lot of attention. The waves at these frequencies can interact with gas molecules possessing dipole moments and change their rotational states. This phenomenon can be utilized for fast scan rotational spectroscopy to detect gas molecules and measure their concentrations. Rotational spectrometers have a wide range of applications including indoor air quality monitoring, detection of harmful gas leaks, breath analyses for monitoring bodily conditions and many others. At the mm and sub-mm wave frequencies, a large bandwidth is available for extremely high data rate communication. Communication over a dielectric waveguide at these frequencies with a loss less than 10dB/m has been proposed to mitigate the complexity of communication over copper wires as well as the integration challenges for optical communication that are being developed to meet the ever-increasing bandwidth demand. The advances of complementary metal-oxide-semiconductor (CMOS) technology have enabled the implementation of mm-wave and sub-mm wave frequency circuits with reduced cost and increased system integration and complexity. A receiver with a radio frequency front-end bandwidth of 95 GHz and noise figure of 13.9 -19 dB for a rotational spectrometer is demonstrated in 65-nm CMOS. In addition, a 300-GHz QPSK transmitter with a 30-Gbps data rate is demonstrated that consumes 180mW for dielectric waveguide communication. The system level tradeoff of a receiver for rotational spectroscopy is first analyzed with a focus on the noise mechanism. A detailed signal-noise interaction derivation due to a 2nd order non-linearity is presented and signal to noise ratio degradation is shown for different modulation scenarios. A receiver front-end using a broadband antenna backed by a phase compensated artificial magnetic conductor reflector, a floating body antiparallel diode pair as the mixing device and a multi-mode isolated broadband hybrid is demonstrated. The receiver also includes an on-chip LO generator using frequency multipliers and capacitive neutralized power amplifiers, an IF cascode low noise amplifier and a baseband power detector. The receiver exhibits a responsivity of 400-1200 kV/W and noise equivalent power of 0.4 to 1.2 pW/√Hz at 225 to 280 GHz. Detection of Ethanol, Propionitrile (EtCN), Acetonitrile (CH3CN) and Acetone in a mixture is demonstrated using the receiver in a rotational spectroscopy setup. This is the first demonstration that a CMOS receiver can be used for rotational spectroscopy and that a CMOS integrated circuit can support an existing application at frequencies above 200 GHz. A heterodyne transmitter with a current mode logic modulator, a multi-stage constant gain and group delay wideband data buffer using coupled resonators, a double balance passive up-conversion mixer using a Marchand balun which acts as built-in LO spur traps, and a quadrature oscillator with quadrature calibration are demonstrated. The transmitter generates the required RF power for the system of -6 dBm and supports a maximum data rate of 30Gbps while consuming 180mW of power resulting in an energy efficiency of 6 pJ/bit. The single channel data rate is almost 2X higher than that of the previously reported CMOS QPSK transmitter and the energy efficiency is among the highest of CMOS QPSK transmitters operating at the similar frequency range.
Author: Shenggang Dong
Publisher:
ISBN:
Category : Electrical engineering
Languages : en
Pages : 0
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Book Description
The sub-terahertz portion of the electromagnetic spectrum can provide a large bandwidth for both wireless communication and wireline communication using dielectric waveguides. To fully exploit the bandwidth, the communication systems inevitably require frequency division multiplexing. Since integrating a highly frequency-selective multiplexer and a de-multiplexer is challenging at these frequencies, use of MSK (Minimum Shift Keying) modulation with reduced out-of-band emission is a potential approach to alleviate this technical challenge. Furthermore, MSK is a constant envelope modulation and allows more power efficient operation of transmitters. This is particularly important at sub-terahertz frequencies, where the power efficiency of circuits is low. Lastly, MSK signals can be demodulated using a phase locked loop (PLL) based receiver that tracks the carrier frequency of signals incident to a receiver, which greatly relaxes the frequency synchronization requirements in both transmitter and receiver. PLL-based receivers are also simple to implement. Although MSK signals have such merits for sub-THz communication, the previously reported carrier frequency of Gilbert-mixer-based MSK transmitters is lower than 60 GHz and data rate lower than 2 Gbps. The maximum data rate of PLL-based receivers is 10’s of Mbps. Increasing the data rate of PLL-based receiver and generation of high-data rate MSK signals are the main topics of this dissertation. First, a 180-GHz MSK receiver using a phase-locked loop (PLL), which self-synchronizes carrier frequency is demonstrated. The mixer first receiver is fabricated in a 65-nm CMOS process. A double balanced anti-parallel-diode-pair sub-harmonic mixer performs the phase detection, reducing the frequency of LO by half. Tunable zeros realized by series inductors are used to improve the stability and to increase the data rate handling capability. Without external LO synchronization, the receiver demodulates MSK signals at 10 Gbps with a bit error rate (BER) of
Author: Yeo Kiat Seng
Publisher: World Scientific
ISBN: 9811202621
Category : Technology & Engineering
Languages : en
Pages : 264
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Book Description
This book addresses in-depth technical issues, limitations, considerations and challenges facing millimeter-wave (MMW) integrated circuit and system designers in designing MMW wireless communication systems from the complementary metal-oxide semiconductor (CMOS) perspective. It offers both a comprehensive explanation of fundamental theories and a broad coverage of MMW integrated circuits and systems.CMOS Millimeter-Wave Integrated Circuits for Next Generation Wireless Communication Systems is an excellent reference for faculty, researchers and students working in electrical and electronic engineering, wireless communication, integrated circuit design and circuits and systems. While primarily written for upper-level undergraduate courses, it is also an excellent introduction to the subject for instructors, graduate students, researchers, integrated circuit designers and practicing engineers. Advanced readers could also benefit from this book as it includes many recent state-of-the-art MMW circuits.
Author: Khaled Khalaf
Publisher: Springer
ISBN: 3030166538
Category : Technology & Engineering
Languages : en
Pages : 109
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Book Description
This book discusses low power techniques for millimeter wave transmitter IC. Considerations for the front-end design are followed by several implementation examples in the 60GHz band in CMOS down to 28nm technology. Additionally, the design and implementation details of digitally-modulated millimeter wave polar transmitters are presented.
Author: Theodore S. Rappaport
Publisher: Pearson Education
ISBN: 0132172283
Category : Computers
Languages : en
Pages : 705
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Book Description
The Definitive, Comprehensive Guide to Cutting-Edge Millimeter Wave Wireless Design “This is a great book on mmWave systems that covers many aspects of the technology targeted for beginners all the way to the advanced users. The authors are some of the most credible scholars I know of who are well respected by the industry. I highly recommend studying this book in detail.” —Ali Sadri, Ph.D., Sr. Director, Intel Corporation, MCG mmWave Standards and Advanced Technologies Millimeter wave (mmWave) is today's breakthrough frontier for emerging wireless mobile cellular networks, wireless local area networks, personal area networks, and vehicular communications. In the near future, mmWave products, systems, theories, and devices will come together to deliver mobile data rates thousands of times faster than today's existing cellular and WiFi networks. In Millimeter Wave Wireless Communications, four of the field's pioneers draw on their immense experience as researchers, entrepreneurs, inventors, and consultants, empowering engineers at all levels to succeed with mmWave. They deliver exceptionally clear and useful guidance for newcomers, as well as the first complete desk reference for design experts. The authors explain mmWave signal propagation, mmWave circuit design, antenna designs, communication theory, and current standards (including IEEE 802.15.3c, Wireless HD, and ECMA/WiMedia). They cover comprehensive mmWave wireless design issues, for 60 GHz and other mmWave bands, from channel to antenna to receiver, introducing emerging design techniques that will be invaluable for research engineers in both industry and academia. Topics include Fundamentals: communication theory, channel propagation, circuits, antennas, architectures, capabilities, and applications Digital communication: baseband signal/channel models, modulation, equalization, error control coding, multiple input multiple output (MIMO) principles, and hardware architectures Radio wave propagation characteristics: indoor and outdoor applications Antennas/antenna arrays, including on-chip and in-package antennas, fabrication, and packaging Analog circuit design: mmWave transistors, fabrication, and transceiver design approaches Baseband circuit design: multi–gigabit-per-second, high-fidelity DAC and ADC converters Physical layer: algorithmic choices, design considerations, and impairment solutions; and how to overcome clipping, quantization, and nonlinearity Higher-layer design: beam adaptation protocols, relaying, multimedia transmission, and multiband considerations 60 GHz standardization: IEEE 802.15.3c for WPAN, Wireless HD, ECMA-387, IEEE 802.11ad, Wireless Gigabit Alliance (WiGig)
Author: Noël Deferm
Publisher: Springer
ISBN: 3319139517
Category : Technology & Engineering
Languages : en
Pages : 188
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Book Description
This book focuses on the development of circuit and system design techniques for millimeter wave wireless communication systems above 90GHz and fabricated in nanometer scale CMOS technologies. The authors demonstrate a hands-on methodology that was applied to design six different chips, in order to overcome a variety of design challenges. Behavior of both actives and passives, and how to design them to achieve high performance is discussed in detail. This book serves as a valuable reference for millimeter wave designers, working at both the transistor level and system level.
Author:
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
Abstract: The challenges in the design of CMOS millimeter-wave (mm-wave) transceiver for Gbps wireless communication are discussed. To support the Gbps data rate, the link bandwidth of the receiver/transmitter must be wide enough, which puts a lot of pressure on the mm-wave front-end as well as on the baseband circuit. This paper discusses the effects of the limited link bandwidth on the transceiver system performance and overviews the bandwidth expansion techniques for mm-wave amplifiers and IF programmable gain amplifier. Furthermore, dual-mode power amplifier (PA) and self-healing technique are introduced to improve the PA's average efficiency and to deal with the process, voltage, and temperature variation issue, respectively. Several fully-integrated CMOS mm-wave transceivers are also presented to give a short overview on the state-of-the-art mm-wave transceivers.
Author: Wei Liat Chan
Publisher:
ISBN: 9789090256245
Category :
Languages : en
Pages :
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Book Description
Author: Ivan Chee-Hong Lai
Publisher: Springer Science & Business Media
ISBN: 1402069995
Category : Technology & Engineering
Languages : en
Pages : 185
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Book Description
Design and Modeling of Millimeter-wave CMOS Circuits for Wireless Transceivers describes in detail some of the interesting developments in CMOS millimetre-wave circuit design. This includes the re-emergence of the slow-wave technique used on passive devices, the license-free 60GHz band circuit blocks and a 76GHz voltage-controlled oscillator suitable for vehicular radar applications. All circuit solutions described are suitable for digital CMOS technology. Digital CMOS technology developments driven by Moore’s law make it an inevitable solution for low cost and high volume products in the marketplace. Explosion of the consumer wireless applications further makes this subject a hot topic of the day. The book begins with a brief history of millimetre-wave research and how the silicon transistor is born. Originally meant for different purposes, the two technologies converged and found its way into advanced chip designs. The second part of the book describes the most important passive devices used in millimetre-wave CMOS circuits. Part three uses these passive devices and builds circuit blocks for the wireless transceiver. The book completes with a comprehensive list of references for further readings. Design and Modeling of Millimeter-wave CMOS Circuits for Wireless Transceivers is useful to show the analogue IC designer the issues involved in making the leap to millimetre-wave circuit designs. The graduate student and researcher can also use it as a starting point to understand the subject or proceed to innovative from the works described herein.
Author: Ali M. Niknejad
Publisher: Springer Science & Business Media
ISBN: 0387765611
Category : Technology & Engineering
Languages : en
Pages : 313
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Book Description
This book compiles and presents the research results from the past five years in mm-wave Silicon circuits. This area has received a great deal of interest from the research community including several university and research groups. The book covers device modeling, circuit building blocks, phased array systems, and antennas and packaging. It focuses on the techniques that uniquely take advantage of the scale and integration offered by silicon based technologies.
